Automatic steering system



Nov. 17; 1953 Filed Feb. 1, 1946 N. B. MURPHY AUTOMATIC STEERING SYSTEM 5 Sheets-Sheet l UHMHN B. MUHPH Y Nov. 17, 1953 N. B. MURPHY AUTOMATIC STEERING SYSTEM 5 Sheets-Sheet 2 Filed Feb. 1, 1946 INVENTOR NUHHHN B. MURPHY TORNEY Nov. 17, 1953 N. B. MURPHY 2,659,554

AUTOMATIC STEERING SYSTEM Filed Feb. 1, 1946 3 Sheets-Sheet 3 INVENTOR NUHMHN B. MURPHY BY 6 I TORNEY Patented Nov. 17, 1953 UNITED STATES PATENT OFFICE AUTOMATIC STEERING SYSTEM Norman B. Murphy, West Englewood, N. J., assignor to Bendix Aviation Corporation, Teterboro, N. J a corporation of Delaware Application February 1, 1946, Serial No. 644,799

6 Claims. (Cl. 244-47) The present invention relates generally to automatic pilot or control systems for mobile craft or the like having novel provisions therefor for imparting an automatic turn to the craft in the manner more fully described and claimed in copending application Serial No. 644,642, filed January 31, 1946, and now matured into U. S. Patent Serial No. 2,589,834, issued March 18, 1952, to A. M. MacCallum, and more particularly to a novel control unit for initiating and controlling such turn.

Where application Serial No. 644,642, now U. S. Patent 2,589,834, deals with the system as a Whole for maneuvering a craft into an automatic turn without calling upon the master instruments to initiate the turn thus leaving the latter free to respond to only those functions of normal course change, rate of course change and attitude change for which they were designed, the present application deals with the novel control unit for the system and the arrangement of instruments thereat for initiating and controlling a desired turn independently of the master instruments.

An object of the present invention, therefore, is to provide an automatic steering system for mobile craft with a novel automatic turn mechanism.

Another object of the invention is to provide a novel automatic turn unit for an automatic pilot or steering system whereby correctly banked turns at any desired rate may be automatically attained.

A further object of the invention is to provide a small, compact and novel control unit for an automatic pilot embodying a novel automatic turn mechanism therein of the character described for controlling the direction and attitude of a craft, the unit being provided with pitch and bank trim knobs for readily trimming elevator and aileron surfaces as required during a linear flight. By manipulation of the pitch trim knob, for example, the craft may be made to climb or dive and will continue to climb or dive at an angle corresponding to the setting of the pitch trim knob until the latter is returned to a central position. Moreover, a single turn control knob is provided on the unit whereby the craft may be made to turn at any desired rate, the correct angle of bank for that turn as well as the necessary amount of elevator trim for that turn being simultaneously introduced upon operation of the turn control knob.

lhe above and other objects and advantages of the present invention will appear more fully hereinafter from a consideration of the detailed description which follows, taken together with the accompanying drawings wherein one embodiment of the invention is illustrated. It is to be expressly understood, however, that the drawings are for the purpose of illustration and description only, and are not designed as a definition of the limits of the invention.

In the drawings wherein like reference characters refer to like parts throughout the several views,

Figure 1 is a diagrammatic illustration of the rudder control system of the novel light-weight automatic pilot of copending application Serial No. 644,642, new U. S. Patent Serial No. 2,589,834;

Figure 2 is a view similar to that of Figure 1 illustrating the aileron and elevator control systems of the automatic pilot of the aforementioned copending application;

) Figure 3 is a detailed view showing the motor control and clutch control wiring hook-up of the system of Figures 1 and 2;

Figure 4 is a perspective view of the novel control unit of the present invention; and

Figure 5- is a diagrammatic illustration of the arrangement of the various controls and their electrical connections of the unit of Figure 4.

Referring now to the drawings and more particularly to Figure 1 thereof for a more detailed description of the present invention, the mechanism for actuating a rudder control surface It comprises a magnetic pick-up unit, generally designated with the reference character II, which may be of the character shown in copending application Ser. No. 624,710, filed October 26, 1945,

and which is rigidly fastened directly to some part of the craft such as the wing, for example, where a minimum of disturbances due to local magnetic fields exists. The pick-up device operates as an earth inductor compass in that for every craft deviation from a prescribed course, however small, the induced voltages at its secondaries 22, 23 and 24 will vary in accordance with and be proportional to the deviation and such variation will be communicated to stator windings 28 of an inductive coupling device 29. A signal will be induced in rotor 30 of device 29 which is amplified within amplifier 33 for energizing an induction motor 36, which is mechanically connected with rotor 30 by way of a shaft 3| for driving the rotor to a null position in which the induced signal will drop to zero.

As will hereinafter more fully appear, motor 36 is locked against rotation during automatic flight so that a signal developed by pick-up device I I as a result of a deviation from a prescribed course will be reproduced within rotor winding aesamsa 30, and since the latter cannot be driven to a null by the motor, the signal thereof is communicated by leads 38 and 39 to the input of a conventional vacuum tube amplifier ill, the output of which energizes a two-phase induction motor 43 for displacing rudder Ill through an electro-magnetic clutch 45. On operating, motor 43 also displaces an electrical follow-up device 41, 49 for develop ing a follow-up signal which is impressed by way of lead 50 on the compass signal at the input of amplifier 40.

In addition to displacement and follow-up signals, motor 33' is also controlledby a signal proportional to the rate of craft turn. Torthis end an inductive transmitter device 51 is provided comprisng three-phase wound stator 53; two phases of which are interconnected througha resistor 59, and a wound rotor 6'8 connected with asuitable source of currentand inductively coupled with the stator. Rotor Gil, further, is mount; ed on a trunnion E of a two degree or freedom gyro for motion therewith. Stator 53 has volt age generated in each of its windings proporuon n respectively, to the angular position [of each of the windings relative to rotor 65 and. the signal resulting therefrom is communicated by lead 6i, which connects stator 58 in series with the stator of the follow-up signal generating clevice to beimpressed upon the direction. and follow-up signals at the amplifier input. A resistor 62 interposed between a lead 63 and lead 6|, is provided so that an initial setting or the amount of rate signal to be fed into the rudder channel may be predetermined.

Signals for the control oi the craft about the bank and pitch axes are derived from take-cits associated with an artificial horizon gyro, generally designated in Figure 2 with the reference character 63, whereby magnetic pick-up device I,I. isstabilized in attitude, i. e., maintained in a. substantially horizontal plane. To this end, inductive bank and pitch signal transmitter device's TI and I38 are provided on gyro 64'. Bank tran mi'tter device TI comprises a wound stator 72 and an inductively coupled rotor winding l3 carried by fgyr o ti'uhnions 6'9 for angular motion therewith. The rotor winding is connected to a suitablesource of current while two of the stator windings are interconnected by a resistor 14 which is center tapped by a lead T5 connecting the stator with the input of the aileron channel o'f an amplifier iii. For a no-ba'nk condition, the normal position of rotor winding "I3 relative to its stator is such that its electrical axis is perpen} dicular to the stator windings and no signal is induced in the rotor winding. Upon a craft bank, rotor winding "I3 moves angularly with trunnion's 69 relative to the stator windings to thereby 'induce a signal in the latter proportional to the amount of craft bank which is amplified within amplifier Iii and supplied at the output thereof by leads I8 to energize the variable phase T9 of a two phase'servo motor 8!], the second phase 131 of which is continuously energized from a suit- .lablesburce of current. Motor8il displaces aileron surface I0 through an electro-m'agnetic clutch 82 and in so doing also displaces an electrical follow-up device 84, 8 5, connected in series with 81 to thereby control the craft about its transvers'ea'xisand thus also stabilize magneticpick up device II, pitch inductive transmitter device 4 88 comprises a fixed wound stator 39, two winch ings of which are interconnected by a resistor 9B, the latter being center tapped by a lead M which connects the stator with the input of a vacuum tube amplifier 92, and a rotor winding 93 inductively coupledwith the stator and connected with suitable source; of current, the rotor winding being carried by trunnion Bl of vertical gyro E4.

Normall the rotor winding assumes a position relative to its stator in which its electrical axis is normal to the stator and no signal is induced in the latter. With craft pitch, however, relative motion is developed by the stator 8G and rotor Qii and, a signal is induced in the stator proportional to craft climb or descent.

The signal so developed within stator 89 is amplified within amplifier 92 and supplied at the output thereof by leads;-94 to the variable phase of .a two phase servornotor the second phase 91 or which is continuously energized from a suitable sourfc'e'. v v Upon theenergization of variable phase 95, motor 96 ,clrives elevator control surfaces 81 through an electromagnetic clutch 98 and a speed reduction gearing 99. Operation of motor 95 causes displacement of a rotor winding I00, which is connected with a suitable source of current, through a speedreductiongear system It, the winding being displaced relative to its wound stator I62 whereby a signal is induced in the latter and fed by way of 'a conductor I03 to the input of amplifier 92, the wound stators 89 and I02 being connected in series with each other and the amplifier input. Wound stator I02 and rotorwinding I09 constitute an inductive followup 'dev'ice which develops a follow-up signal with each craft deviation about its transverse axis, the signal being "added algebraically to the pitch signal for elevator control. V The system thus far described constitutes an all electric automatic steering system providing three axes of "control, i. e;, with a givencourse and attitude established manually a subsequent engagement of the system will automatically maintain the craft on that courseand in that attitude. In order to provide the human pilot with ,a readily accessible control for throwing the craft into an automatic turn, therudder turn, aileron turnfandiel'evator turn devices I04, I05 and I06, are provided, each constituting a potentiometer having a resistor m1, IElB'and I09 anda wiper or contactarm I I0, III and H2, wiper arm IIO befingconnectedin series'by way o'f a lead 83 with wound stator "58 of the rate inductive device, wound stator 49 of theinductive follow-up device and input of amplifier wiper arm III being connected in series by Way of a lead I I3 with the wound stator of the inductive bank followmp idevice, wound stator I2 of the bank inductive tr'ansn'oitter[deviceandthe input of amplifier-l6,

.whilewiper arm H2 is connected in series byway 'Qfia lead II I'uvith the wound stator m2 of the indiictive pitch tollow-up device, wound stator '89 of the'pitch inductive transmitter device and theiinput of amplif er 92.

Eachfpotentiometer resistor I01, I68 and I09 is connected across a related secondary winding II 5, 'II6 and I I'? of'transformers having primary windings I I8, 'IIiland energized from a suitable alternating current source. N orinallyQwiper relative to their resistors I01, I08 and I09, rudder, aileron and elevator signals are developed independently of the magnetic pick-up device II, the rate of turn gyro and the pitch and bank take-offs of the gyro vertical to deflect rudder, aileron and elevator surfaces to direct the craft into the degree of turn called for by the setting of the wiper contacts. In the aileron and elevator channels, the signals introduced by the displacement of wiper contacts III and H2 relative to their resistors, deflect the aileron and elevator surfaces until the desired craft pitch and bank are attained, whereupon, resulting from the craft attitude change, signals are developed by the bank and pitch take-offs H and 88 which will wash out the signals set in by movement of wiper contacts III and H2 when the craft attitude set in by movement of the wiper contacts has been attained. Subsequent deviation from the required craft attitude is under the primary control of the gyro bank and pitch take-offs.

Inasmuch as up-elevator is required in the event of either a left or right turn, the pitch turn device I06 differs from the rudder and aileron turn devices I04 and I05 in that secondary winding II1 of the former is connected at one end by way of a lead I2I with the opposite end of resistor I09 while the opposite end of secondary winding H1 is connected with the center of resistor I09 by way of a lead I22. By reason of such an arrangement, motion of wiper contact H2 in either direction from its central point on resistor I09 will provide a signal in one direction only, i. e., an up-elevator signal, as distinguished from the reversing signal introduced by the wiper contact I II by its movements from one side of its central position to the other side on resistor I08, for example.

During an automatic turn it is necessary toeifectively disconnect the magnetic pick-up device I I from the rudder channel or otherwise any attempted craft turn would be nullified by device II, the latter acting to maintain the craft on its previously prescribed course. To this end, motor 36 which normally drives rotor 30 of the inductive coupling device 29 to its null position is provided with an electromagnetic brake in the form of a plunger I23 which is maintained by a spring I24 out of engagement with the rotor of the motor. The plunger is inductively associated with a coil I25 which connects through leads I26, a turn switch I21, leads I28 and a clutch switch I29 with a battery I30. Also connected, as partly shown in Figure 3, for energization by the closure of clutch switch I29 are coils I3I, I32 and I33 for engaging clutches 45, 82 and 98 whereby rudder servomotor 43 is driveably engaged with rudder surface I0, aileron servomotor 80 is driveably engaged with aileron surfaces and elevator servomotor 96 is driveably engaged with elevator surfaces 81.

During straight automatic flight, clutch switch I29 is closed to thereby establish a driveable connection between the servomotors and their related control surfaces and turn switch I2l is likewise closed thereby energizing coil I so that plunger I23 brakes the rotor of motor 36 against rotation so that any craft deviation in azimuth develops a signal in rotor winding by the operation of the magnetic pick-up device II which acts to operate servomotor 43 and thereby actuate rudder surface I0.

With the initiation of an automatic craft turn, I. e., when wiper contacts IIO, III and H2 are displaced relative to their resistors I01, I06 and I09, turn switch I21 is opened to deenergize coil I25 whereupon spring I24 retracts plunger I23 from engagement with motor 36 so that the latter is free to rotate in response to signals developed within rotor winding 30. Thus, during an automatic turn, even though magnetic pick-up device II is constantly developing a signal proportional to the amount of craft displacement in azimuth which signal is reproduced within rotor winding 30, the motor 36 being free to turn, drives rotor 30 to its null so that no displacement signal is available from pick-up device II for the rudder channel during such a turn.

By providing an arrangement whereby motor 36 is locked against rotation during straight automatic flight and is unlocked for rotation and operation during manual flight or during an automatic turn, a novel synchronization feature is presented whereby the system is always in synchronism, i. e., prior to the initiation of straight automatic flight, the rotor winding 30 of the inductive coupling device is at its null position to immediately take over control of the rudder surface. In response to any deviation from a prescribed course, subsequent to pilot engagement, a signal is developed within winding 30 proportional to the deviation and since motor 36 is braked or locked and cannot drive winding 30 to its null, the signal is communicated from Winding 36 to operate servomotor 43.

During straight automatic flight, switches I21 and 26 are closed but during an automatic turn switch I21 is opened to free motor 36 for operation. During manual flight, on the other hand, clutch switch I29 is opened to discomiect the servos and permit manual control of the surfaces. At such time, even though turn switch I21 is closed, coil I25 is deenergized, as soon as it connects with battery 30 through the clutch switch, to thereby release motor 36 for operation.

Even though the rudder channel has been shown as provided with an amplifier 33 and aileron and elevator channels with separate amplifiers I6 and 92, it is to be understood that but one amplifier is needed containing all three channels as shown in copending application Serial No. 516,488 filed December 31, 1943.

Under certain conditions it is desired to trim the rudder, aileron and elevator surfaces and to this end novel rudder trim, aileron trim and elevator trim devices I35, I36 and I31 are provided. Rudder trim device I35 comprises a potentiometer having a resistor I38 connected across a secondary'winding I39 of the transformer having winding H8 for its primary. A central tap of the secondary winding is grounded by way of a conductor hi0 while resistor I38 is provided with a wiper contact I-I which is arranged at a normally central point on resistor I36, wiper I4! being connected by way of a lead I 32 with a central portion or secondary winding II5. Thus arranged, rudder trim device I35 is in series with rudder turn device I04, the rate inductive device, the rudder inductive follow=-up device and the input of the rudder channel of the amplifier.

Aileron trim device I36 comprises a potentiometer having a resistor I44 connected across a secondary winding I45 of the transformer having winding II9 for its primary. A central tap of the secondary winding is grounded by way of a conductor I41 while resistor I44 is provided with a wiper contact I48 which is arranged at a normally centralpoint on resistor I44, wiper channel of the amplifier. 'pitch trim, wipercontactsMB and I53 are dis-- 1. being connected by way of :a-lead I40with a central portion of secondary winding. II6.' as will be apparent, aileron trim device I36 1s 1n series with aileron turn device I05,-stator 65 of thebank follow-up device, stator 12. of the bank take-off device and the input of the aileron channel of the amplifier.

Elevator trim device I31,- on theother hand,

comprises a potentiometer having a resistor I56 connected across a secondary winding I5I of the vtransforinerhaving winding I20. for its primary.

-;able.leadswith its .secondarylwinding 245, a center tap of the secondary being grounded by way of a lead 241 while wiper contact 246 connects by way of a lead 249 with a central point of secondary winding 2I6.

Supportedupon. shaft I69 of the pitch trim knob IE1 is wiper contact 253 which normally restslon a central point of its resistor 250 which A center tap of the secondary winding is grounded I 'by way of a conductor I52 while resistor -I50 is provided with a wiper contact I53 which is arranged at a normally central "point on resistor I50, wiper I53 being connected by way of a'lead I54 with secondary-winding II1 at that end --which connects by Way of a lead I22 with the center tap of resistor I of the pitch turndevice I06. Thus arranged, elevator trim device I31 is in series with elevator turn device I06, the stator I02 of the-pitch follow-up device, stator 89 of the gyro pitch take-off device and the input of the elevator channel of the amplifier.

If left or right rudder trim isrequired, wiper arm I is displaced relative to resistor I38, above or'below the center point thereoiandthe re quired signal is fed by lead I42 into the rudder Similarly forbank or matic turn control mechanism hereof, itis shown in Figure 4 as comprising a substantially rectangular casing I60 having an apertured rear flange ISI for attaching the. unit to a wall of the-craft cockpit for ready access to the human pilot. As shown, casing I60 at its top is provided with an automatic turn knob I62 havinga shaft I63 -(Figure suitably journalled within the casingand a' bank trim knob I64 arranged to the. rear of the casing and carrying a shaft I65 arranged transversely to turn shaft I63. In

.' addition, rudder trimand pitch trim knobs I66 and I61 are provided on casing I60, the former being located on the underside of the casing and supporting a shaft I68 and the latter being located at the top side of the casingand carrying a shaft I69 thereon.

For reasons of clarity, the various components are shown diagrammatically within casing I60 and parts in Figure 5 corresponding to like parts illustrated in Figures 1 to. 3, inclusive, are designated with the same reference character plus one-hundred. To this end, turn shaft-l63 carries suitably insulated therefrom bank turn wiper contact 2, pitch turn Wiper contact H2 and rudder turn wiper contact 2 I0. Each of the wiper contacts normallyengages at a central point with its related, resistor 206, 209 and 201, the resistors being shown as arcuate in shape and coaxial with the turn shaft. Resistor 208 connects by Jsuitablealeads with its. secondary winding 2:6, resistor Nil-connects in the same: manner lwith the secondaryuwinding 2I.1 whileresistor 201 connects with its secondary winding 2 I 5. Shaft I65 of bank .trim knob I64, supports thereon a ..wiper.contact '240 which normally rests on a central point oflts -resistor -244 the latter being arcuate inlshape; and connected byway oizsuit is arcuate inshape and. which at its outer ends connects by suitable .leads with its secondary :winding I, a-center tap of said secondary being grounded by way of alea'd 252 while wiper contact 253 connects by way of a lead 254 with one end of secondary winding 2I1, such end of the secondary being connected'with a center point ofresistor. 209 by way of a conductor 222 while the opposite end of secondary 2I1 connects with an oppositeend of resistor 200 by Way of a 7 lead 221.

Rudder trinrknob I66 supports on its shaft I68 awiper-contact 24I which normally rests on a central point of its resistor 238 which is arouate in shapeand which at its outer ends connects by suitable leads with its secondary winding 239, a center tap of such secondary being grounded by way or a lead 240 while wiper contact 24Iconnects by way of a lead 242 with a I of thevariouscomponents comprising the auto y 7 central point of secondary winding 2N5. Although separate primary transformer windings H8, H9 and 28 have been shown in Figures v1 and 2, it is to be understood that but a single transformer primary I10 within the controller unit is required.

fi'lie outer extremity of turn shaft is provided with a cam I'll havinga flat side normally engaging a pivoted leaf arm. 3E2 rests against and is insulated from a resilient l'i'3 carrying thereon a contact lid in engagem nt with a contact I'l-Ei carried a IL arm the two contact arms being suitably insulated from each other. Contact l'ili is connected by way of a lead 226 with battery 23b and contact lid is connected by way of a similar lead with a coil corresponding to coil IE5 of Figure Contacts I'lfl-li6 thus define the turn switch l2"! of Figure l which is normally closed to ener- "gize coil I25 and brake or lock motor against operation. 'With'the setting of "turn knob however, cam ill breaks contac ll -llii to open the switch and release motor for operation. In addition, the controller unit is provided witha clutch switch 229 (Figure 4) which corresponds to clutch switch I26 of Figure 1.

For trimming rudder or aileron; the human .pilot turns knobs IE6 or i i-i in one direction or another from their normally central position on resistors 238 or 2 26 whereupon a direction or bani:

signal is introduced into the rudder or aileron channel of the amplifier as heretofore described may be forced into a climb by cperat' to actuate rudder or aileron surfaces to obtain the desired rudder or ailerontrim.

With the automatic pilot engaged, the craft pitch trim knob 351 to displace wiper from its normally central position in one direction related to its resistor. whereby a signal is developed andfed into the elevator channel of the amplifier to deflect the elevator surfaces and cause the craft to climb and it will be maintained in such climb until knob I51 is returned to neutral, i. e.,

ated to displace wiper arm 253 in an opposite direction relative to resistor 256.

If, during the course of linear flight with the.

automatic pilot engaged, it is desired to change course, the human pilot need merely displace turn knob I52 an angular amount proportional to the rate of turn desired. Displacement of knob I62 actuates cam ill to open contacts ilk-I (switch [2! of Figure l) to unlock motor 35 for operation whereby rotor winding as is constantly driven to a null and no signal from the magnetic pick-up device H is fed into the rudder during the turn. Displacement of knob I62, furthermore, results in displacement of wiper contacts 2H, 2|2 and 2m to feed proper signals into the aileron, elevator and rudder channels, an up-elevator being called for in each instance notwithstanding the direction of turn.

By the operation of turn control knob [62 the conditions for a desired turn are automatically established without loading or calling upon the rate gyro or the artificial horizon gyro to initiate the turn. The signals set in by the turn knob are fed into their respective networks to control related surfaces to swing the craft into a desired turn at the current angle of bank for that turn together with the necessary up -elevator. The theory and operation underlying the control presented by turn knob 152 is generally similar to that underlying the arrangement shown in copending application Serial. No. 595,236, now U. S. Patent Serial No. 2,516,796, filed May 22, 1944.

The novel automatic turn control unit above described is of such character that extreme flexibility of control is provided by the automatic pilot which makes it possible to execute maneuvers by turning appropriate controls. For example, sharply banked turns may be made by actuation of turn control knob [62, the craft immediately returning to straight flight when the knob is rcturned to its central position. Steep climbs or dives may be made by operating pitch trim knob I61. Moreover, a combination of turns and climbs or turns and dives may also be executed or the craft quickly thrown from a correctly banked turn in one direction to a correctly banked turn in an opposite direction.

Although but a single embodiment of the invention has been illustrated and described in detail, it is to be expressly understood that the invention is not limited thereto. Various changes may also be made in the design and arrangement of parts without departing from the spirit and scope of the invention, as the same will now be understood by those skilled in the art. For a definition of the limits of the present invention, reference will be had primarily to the appended claims.

What is claimed is:

1. A turn control unit for the automatic pilot of an aircraft, said automatic pilot having means for maintaining the craft on a predetermined course, means for maintaining the craft in a predetermined bank condition, and means for maintaining the craft in a predetermined pitch attie tude, said means for maintaining the craft on a predetermined course including a course change responsive means having a displaceable signal generator, actuating means operatively connected with the latter for displacing said generator to a non-signal generating position, and control means operatively connected with said actuating means which when operated in one manner make the actuating means effective on said generator to displace the latter whereby no signal is available from the course change responsive means for maintaining said craft on a predetermined course and which when operated in another manner make the actuating means ineffective on said generator whereby the signal of the latter operates said course maintaining means to maintain said craft on the predetermined course, said turn control unit comprising displaceable turn, bank and pitch signal generators for controlling said course maintaining means, bank condition maintaining means, and pitch attitude maintaining means, a common member supporting said turn, bank, and pitch signal generators for displacement, a manually operable member operatively connected with said common member for displacing said common member from a reference position to bank and turn the craft, and means operatively connecting said common member with said control means and operative in response to movement of said manually operable member for making the actuating means effective on said first mentioned signal generator.

2. In an automatic pilot for aircraft having rudder, aileron, and elevator surfaces, said automatic pilot having servomotors associated with said surfaces for actuating the same and including course change responsive means operatively connected to the rudder surface servomotor and attitude responsive means operatively connected to the aileron and elevator surface servomotors, said course change responsive means including a displaceable signal generator, actuating means connected to said generator and for displacing the latter to a non-signal generating position, and control means connected with said actuating means which when operated in one manner make the actuating means effective on said generator to displace the latter whereby no signal is available from the course change responsive means for operating said rudder servomotor and which when operated in another manner make the actuating means ineffective on said generator whereby the signal of the latter operates the rudder servomotor, a turn control unit comprising displaceable turn, bank, and pitch signal generators controllin the rudder, aileron, and elevator servomotors, a common and displaceable member supporting said turn, bank, and pitch signal generators in tandem, a manually operable device connected with said common member for displacing it from a reference position to bank and turn the craft, and means operatively connected with said common memher and said control means and operative by said manually operable device for making the actuating means effective on said first mentioned signal generator.

3. In an automatic pilot for an aircraft having rudder, aileron, and elevator surfaces, said automatic pilot having servomotors actuating said surfaces and includin course change responsive means controlling the rudder surface servomotor and attitude responsive means controlling the aileron and elevator surface servomotors, said course change responsive means having a displaceable signal generator, actuating means operatively connected with said generator for displacing the latter to a non-signal generating position, and control means operatively connected with said actuating means for rendering said actuating means effective and ineffective to displace said generator to develop a signal to control the rudder surface servomotor, a turn control unit comprising turn, bank, and pitch signal developing potentiometers having displaceable contact arms for controlling the rudder, aileron, and

elevator surface, servomotors, a di'splaceable member supporting said contact arms,,a manually operable member operatively connected. with said displaceable member for moving the displaceable member from a. reference position to bank and turn the aircraft, and meansinterconnecting said displaceable member and said control means and operative by said manually operable member for making the. actuating means effective on said first mentioned signal enerator.

4.. In an aircraft, automatic pilot having a rudder servomotor and course change responsive means connected to. said servomotor for controlling the motor, the course change responsive means including a displaceable signal generator, actuating means associated with said generator for displacing the generator to a non-signal generating position, and control means operatively connected with said. actuating means which when operated inone manner eifect said actuating means so, that no signal is available from the course change responsive means for rudder servomotor control and which when operated in another manner effect said actuating means so that a signal is available to control the rudder servoinotor, a turn control means comprising a displaceable turn signal generator for controlling the servomotor, a manually operable control member connected to said turn signal generator for displacing the latter and means operatively connected with said control means and said manually operable member and operable by said manually operable member for affecting the actuating means so that no signal is available from said firstsignal generator.

5. In an aircraft automatic pilot having a surface displacing motor and position change responsive means connected to said motor for operating the latter; saidposition change responsive means including a displaceable signal generator, an actuating means operatively connectedv with said generator for displacing the latter to a non-signal generating position, and control means connected with said actuating means which when operated in one manner make the actuating means efiective on said generator to displace the latter whereby no signal is available from the position change responsive means for motor control and which when operated in another manner, make the actuatingmeans ineflfective on said generator whereby the signal of the latter controls the motor, a turn control 12 means comprising a displaceable position change signal generator for, controlling the motor, a manually operable control member operatively connected with said position change, signal gen erator for displacing the latter, and means operatively connected with said control means and said manually operable member and operable by said manually operable member for making the actuating means eiiective on said first mentioned signal generator.

6. In a plurality of motor control circuits, each circuit comprising a motor and a two-part inductive device operatively connected with said motor and wherein each inductive device has one part movable relative, to the other to deelop a control signal for said motor and a separate means operatively connected with each of said movable. parts for moving the latter, a, control unit for said circuits comprising a plurality of impedance units including resistors and coacting wipers, an adjusting means operatively connected with each of, said wipers for moving the latter to develop a control signal for a respective motor, a unitary member connected to all of said adjusting means, a manually operable means connected to said unitary member for moving the latter to develop a signal for each of said motors, a means completing each circuit by connecting said impedance device in series with said inductive device to said motor, and means on said unitary member connected with one of said, circuits for rendering upon movement of said unitary member from a predetermined position a selected inductive device ineiTective to control its associated motor.

NORMAN B. MURPHY.

References Cited in the file of this patent UNITED STATES PATENTS Number Name I Date 1,466,293 Brooks Aug. 28, 1923 1,973,453 Whiting Sept. 11, 1934 2,005,530 Boykow June 18, 1935 2,196,385 De Florez Apr. 9, 1940 2,203,671 Carlson June 11, 1940 2,471,821 Kutzler et. a1. May 31, 19419 2,516,641 Murphy July 25, 1950 2,516,796 Noxon et al. July 25, 1950 2,589,834 MaoCallum Mar. 16, 195.2

OTHER REFERENCES Electronics of October, 1944, pages 110, 111, 112, 113, 114, 115, 116, 117. 

